JP3309309B2 - Brazing electrode parts and brazing electrodes for discharge lamps - Google Patents

Brazing electrode parts and brazing electrodes for discharge lamps

Info

Publication number
JP3309309B2
JP3309309B2 JP01288098A JP1288098A JP3309309B2 JP 3309309 B2 JP3309309 B2 JP 3309309B2 JP 01288098 A JP01288098 A JP 01288098A JP 1288098 A JP1288098 A JP 1288098A JP 3309309 B2 JP3309309 B2 JP 3309309B2
Authority
JP
Japan
Prior art keywords
brazing
electrode
discharge lamp
pipe
brazing material
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Fee Related
Application number
JP01288098A
Other languages
Japanese (ja)
Other versions
JPH11213946A (en
Inventor
重彦 高岡
秀男 相馬
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
ALMT Corp
Original Assignee
ALMT Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by ALMT Corp filed Critical ALMT Corp
Priority to JP01288098A priority Critical patent/JP3309309B2/en
Publication of JPH11213946A publication Critical patent/JPH11213946A/en
Application granted granted Critical
Publication of JP3309309B2 publication Critical patent/JP3309309B2/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

Links

Landscapes

  • Discharge Lamp (AREA)
  • Vessels And Coating Films For Discharge Lamps (AREA)

Description

【発明の詳細な説明】DETAILED DESCRIPTION OF THE INVENTION

【0001】[0001]

【発明の属する技術分野】本発明は,メタルハライドラ
ンプやナトリウムランプ等の金属蒸気放電灯に用いられ
る高融点金属製電極に関する。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a refractory metal electrode used for a metal vapor discharge lamp such as a metal halide lamp and a sodium lamp.

【0002】[0002]

【従来の技術】従来,メタルハライドランプやナトリウ
ムランプ等の金属蒸気放電灯が知られている。この金属
蒸気放電灯は,ハロゲン化金属やアマルガム等を封入
し,これらの金属の発光スペクトルにより光色を変化さ
せ,効率や演色性を改善したものである。
2. Description of the Related Art Conventionally, metal vapor discharge lamps such as metal halide lamps and sodium lamps are known. This metal vapor discharge lamp is one in which a metal halide, amalgam, or the like is sealed, the light color is changed by the emission spectrum of these metals, and the efficiency and color rendering are improved.

【0003】図5は従来のメタルハライドランプの構造
を示す概略断面図である。図5を参照すると,この金属
放電灯50は,放電電極である一端側にWコイル11を
備えた棒状のW電極12は,モリブデン(Mo)箔13
を介してMoリード14にそれぞれ抵抗溶接などで接続
されている。この接続部は,放電灯発光部を構成するア
ルミナガラス管15の端面で封入されている。これらの
部品を組立後,ハロゲン化金属をアルミナガラスからな
る放電灯発光部に投入,約1500℃にて加熱封止して
いる。
FIG. 5 is a schematic sectional view showing the structure of a conventional metal halide lamp. Referring to FIG. 5, the metal discharge lamp 50 has a rod-shaped W electrode 12 having a W coil 11 at one end, which is a discharge electrode, and a molybdenum (Mo) foil 13.
Are respectively connected to the Mo leads 14 by resistance welding or the like. This connection part is sealed at the end face of the alumina glass tube 15 constituting the discharge lamp light emitting part. After assembling these parts, the metal halide is put into a discharge lamp light emitting part made of alumina glass, and heated and sealed at about 1500 ° C.

【0004】しかしながら,アルミナガラス管15にハ
ロゲン化金属投入口があるため封止時,アルミナガラス
管15を加熱する必要がある。その際,内部に投入した
ハロゲン化金属が加熱時に,蒸発,リークしてしまう。
さらにそのリーク量が不安定であるため,放電灯内の残
量を一定とすることが難しい。
However, since the alumina glass tube 15 has a metal halide inlet, it is necessary to heat the alumina glass tube 15 during sealing. At that time, the metal halide charged inside evaporates and leaks during heating.
Further, since the leak amount is unstable, it is difficult to keep the remaining amount in the discharge lamp constant.

【0005】その欠点を改善するため,例えば,特開平
7−176296号公報(以下,従来技術1と呼ぶ)に
上記のMo箔13を白金パイプからなるサポートに変え
たものが開示されている。この従来技術1においては,
白金パイプの両端を放電灯本体部の内外に突き出した状
態で外周面で封入した構造である。封入後,白金パイプ
を介してハロゲン化金属を投入し,白金パイプ部を加熱
封止する。この場合,アルミナガラス部は加熱されない
ため,内部のハロゲン化金属の飛散が少く放電灯内の残
量が安定する。
[0005] In order to improve the drawback, for example, Japanese Patent Application Laid-Open No. Hei 7-176296 (hereinafter referred to as "prior art 1") discloses a structure in which the Mo foil 13 is replaced with a support made of a platinum pipe. In this prior art 1,
This is a structure in which both ends of a platinum pipe protrude into and out of the discharge lamp main body and are sealed on the outer peripheral surface. After encapsulation, a metal halide is introduced through a platinum pipe, and the platinum pipe is heated and sealed. In this case, since the alumina glass part is not heated, the scattering of the metal halide inside is small and the remaining amount in the discharge lamp is stabilized.

【0006】しかしながら,白金パイプは強度が低くさ
らに熱膨張係数が約11×10-6とアルミナガラスの約
8×10-6に比し大きいため封止の際,白金パイプの方
が大きな熱収縮を生じアルミナガラス管15との間に微
小の隙間が発生しやすい。そのため,微小リークが発生
する確率が高い等の問題がある。
However, the platinum pipe has a low strength and a thermal expansion coefficient of about 11 × 10 −6, which is larger than that of alumina glass of about 8 × 10 −6. And a minute gap is easily generated between the alumina glass tube 15. Therefore, there is a problem that the probability of occurrence of a minute leak is high.

【0007】それに対し,高温強度が高く熱膨張係数が
アルミナガラスと比較的近く,かつ小さいMoをパイプ
形状とし白金パイプに変わり使用することが考えられて
いる。
On the other hand, it has been considered that Mo is formed into a pipe shape having a high temperature strength and a relatively high thermal expansion coefficient relatively close to that of alumina glass, and is used instead of a platinum pipe.

【0008】一般に,Moパイプは,棒材をガンドリル
等により貫通穴を開け素管とし,管引き,切断加工等に
より必要サイズのイプを製造している。またサイズに
よっては圧延あるいは鍛造等により加工した板からリン
グ形状を切り出したり,または粉末冶金法によりリング
状にプレスし焼結する等により製造される。
[0008] Generally, Mo pipe, the bar and blank pipe drilled through holes by gun drill or the like, Kanbiki manufactures pipes of the required size by cutting or the like. Further, depending on the size, it is manufactured by cutting a ring shape from a plate processed by rolling or forging, or pressing and sintering into a ring shape by powder metallurgy.

【0009】[0009]

【発明が解決しようとする課題】しかしながら,Mo
は,難加工性の金属であり,管引き時大きな加工率での
加工が困難であるため,所定のサイズまで多くのダイス
引き工程を必要とし,また割れなどの不良が発生し歩留
まりが悪いなどの問題がある。
SUMMARY OF THE INVENTION However, Mo
Is a difficult-to-work metal, and it is difficult to work at a high processing rate during pipe drawing. Therefore, many die drawing steps are required up to a predetermined size, and defects such as cracks occur and the yield is poor. There is a problem.

【0010】さらに,上記棒材および板からパイプ状と
する加工では,製品の部分よりも加工により取り除いた
部分の方が多くなる場合も多い。すなわち歩留が極度に
悪く,資源やエネルギーの使用量も大きくなり,コスト
高の要因となっている。
Further, in the processing of forming a pipe from the bar and the plate, there are many cases where a portion removed by processing is more than a part of a product. That is, the yield is extremely poor, the amount of resources and energy used is large, and this is a factor of high cost.

【0011】また,板材から切り出す方法では板材の厚
みが長さの限界となり,長尺の製品の製造は困難であ
る。
Further, in the method of cutting from a plate material, the thickness of the plate material is limited to its length, and it is difficult to manufacture a long product.

【0012】一方,Mo焼結品では,加工量が大幅に減
少する利点をもつが,密度が充分上がらないため強度面
で不安がある。
[0012] On the other hand, the Mo sintered product has an advantage that the processing amount is greatly reduced, but there is a concern about strength because the density is not sufficiently increased.

【0013】そのため,曲げ加工を施した板の両端部を
接合することにより,パイプ状部材を形成する方法が強
く要求されている。
Therefore, there is a strong demand for a method of forming a pipe-shaped member by joining both ends of a bent plate.

【0014】また,W電極とMoサポートの端面を接合
した場合においても,強度低下の不安のない接合方法が
強く要求されている。そのため,WとMoの接合方法,
即ち,W電極とMoパイプの接合方法が問題となる。
[0014] Even when the W electrode and the end face of the Mo support are joined together, there is a strong demand for a joining method which does not cause a decrease in strength. Therefore, the joining method of W and Mo,
That is, the method of joining the W electrode and the Mo pipe becomes a problem.

【0015】通常は,WとMoは,抵抗溶接により接合
されているが,W及びMoとも高融点金属であり,かつ
電気伝導性,熱伝導性がよいため溶接性が悪く,接合強
度に不安がある。
Normally, W and Mo are joined by resistance welding. However, both W and Mo are refractory metals and have good electrical and thermal conductivity, so that the weldability is poor and the joining strength is unstable. There is.

【0016】したがって,W,Mo等の高融点金属に適
用が考えられる接合方法としては,アーク,TIG,レ
ーザー,電子ビーム等を用いた融接接合,ろう接接合,
拡散接合,リベット止めおよびボルト止め等の機械的接
合などがある。
Therefore, welding methods that can be applied to refractory metals such as W and Mo include fusion welding using an arc, TIG, laser, electron beam, etc., brazing welding,
Examples include diffusion bonding, mechanical bonding such as riveting and bolting.

【0017】この中で,融接は母材の溶接しようとする
部位を加熱し,母材のみか,又は母材と溶加材とを融合
させて溶融金属を作り,これを凝固させ接合する方法
で,鉄系金属を中心に広く構造体の製作に使用されてい
る。しかし,融接法では母材を溶解する必要があるた
め,母材であるW材の融点以上の温度に加熱することが
必須である。また,母材の溶解,凝固を伴うため組織変
化,すなわち再結晶およびその粗大化が避けえないため
残留応力および組織変化により融接継ぎ手部近傍の脆
化,強度低下が生じる。そのため,特に溶解,凝固にと
もなう結晶粒粗大化による脆化が顕著なW,Moなどの
難溶融性金属に対して適用が困難であるまた,W同士,
Mo同士の拡散接合では,再結晶温度以上において初め
て接合可能となるため結晶粒の粗大化による脆化が生じ
る。そこで,接合温度をさげるため,Ni箔等のインサ
ート材を使用することも検討されている。しかしなが
ら,その場合,使用温度によっては金属間化合物を生成
し脆化が生じる。たとえば,Ni/Wでは約1000℃
でNi−W金属間化合物を,Ni/Moでは約800℃
でNi−Mo金属間化合物を生成する。
Among these, fusion welding heats a portion of the base material to be welded, and produces a molten metal by melting only the base material or the base material and the filler metal, and solidifies and joins the molten metal. It is widely used in the fabrication of structures, mainly iron-based metals. However, since the base material needs to be dissolved by the fusion welding method, it is essential to heat the base material to a temperature higher than the melting point of the W material. In addition, since the melting and solidification of the base material accompany the structural change, that is, recrystallization and its coarsening are unavoidable, the residual stress and the structural change cause embrittlement near the weld joint and a decrease in strength. Therefore, it is particularly difficult to apply to hard-to-melt metals such as W and Mo, which are remarkably embrittled by crystal grain coarsening accompanying melting and solidification.
In diffusion bonding between Mo, bonding becomes possible only at a recrystallization temperature or higher, so that embrittlement occurs due to coarsening of crystal grains. Therefore, use of an insert material such as Ni foil has been studied to reduce the joining temperature. However, in that case, depending on the use temperature, an intermetallic compound is formed and embrittlement occurs. For example, about 1000 ° C for Ni / W
At about 800 ° C. for Ni / Mo
Produces a Ni-Mo intermetallic compound.

【0018】また,リベットまたはボルトによる機械的
締結は,古くから適用されており強度的にも安定してい
るが,小型部品には適用が難しく,また接合面の密着性
に問題がある。
Although mechanical fastening with rivets or bolts has been used for a long time and is stable in strength, it is difficult to apply to small parts and there is a problem in the adhesion of the joining surfaces.

【0019】また,ろう接は母材を溶融することなく,
母材よりも低い融点をもつ金属の溶加材(ろう材)を溶
融させ,毛細管現象を利用し接合面の隙間に行き渡らせ
て接合を行う方法である。そのため,溶解,凝固にとも
なう結晶粒粗大化や金属間化合物の生成による脆化が生
じないほか,施工温度が低いため熱応力を抑えることが
できるとともに,母材の組織変化がない等の利点があ
る。さらに,難溶融性金属のように,母材溶解に対して
高エネルギーが必要な場合,あるいは凝固時に割れが生
じやすい材料に適している。
In addition, brazing does not melt the base material,
This is a method in which a filler metal (brazing material) having a melting point lower than that of the base material is melted, and the molten metal is spread over the gap between the joining surfaces by utilizing the capillary phenomenon. Therefore, there are advantages such as crystal grain coarsening due to melting and solidification and embrittlement due to formation of intermetallic compounds do not occur, and thermal stress can be suppressed due to low construction temperature, and there is no structural change in the base metal. is there. Furthermore, it is suitable for materials that require high energy for melting the base material, such as hardly meltable metals, or for materials that are liable to crack during solidification.

【0020】例えば,WおよびMo用ろう材としては,
低温域(800℃以下)では銀ろう,高温域ではRu−
Mo共晶合金ろう材が用いられている。銀ろうでは,ろ
う接温度が低いため当然高温での使用は不可能である。
また,融点以下の使用においても軟化温度がさらに低い
ため,強度低下の不安も大きい。
For example, as a brazing material for W and Mo,
Silver brazing at low temperature (800 ° C or less), Ru- at high temperature.
Mo eutectic alloy brazing material is used. Silver brazing cannot be used at high temperatures because of its low brazing temperature.
In addition, the use of a material having a melting point or lower has a further lowering of the softening temperature, so that there is a great concern that the strength is reduced.

【0021】一方,Ru−Mo共晶合金ろう材において
は高温での強度低下の不安が少ないが,ろう接温度が2
000℃と高いため,WおよびMo母材の脆化が問題と
なり,強度低下の大きな問題が有るため,できるだけろ
う接部材の使用に問題のない範囲でろう接温度の低く,
接合強度の高いろう材が望ましい。
On the other hand, in the case of the Ru—Mo eutectic alloy brazing material, there is little concern about a decrease in strength at high temperatures, but the brazing temperature is 2%.
Since the temperature is as high as 000 ° C., embrittlement of the W and Mo base materials becomes a problem, and there is a major problem of strength reduction.
A brazing material having a high bonding strength is desirable.

【0022】そこで,本発明の一技術的課題は,接合強
度に優れ母材の脆化の恐れの少ないパイプ状サポートが
ろう接により製作可能となり,さらに,前記パイプ状サ
ポートとW電極もろう接により接合可能となり,安定し
た接合部をもつ,ろう接電極用部品とそれを用いた放電
灯用ろう接電極とを提供することにある。
Therefore, one technical problem of the present invention is that a pipe-shaped support which has excellent bonding strength and is less likely to cause brittleness of a base material can be manufactured by brazing, and the pipe-shaped support and the W electrode are also brazed. Accordingly, it is an object of the present invention to provide a brazing electrode component and a brazing electrode for a discharge lamp using the same, which can be joined and have a stable joint.

【0023】また,本発明のもう一つの技術的課題は,
上記ろう接電極用部品を金属蒸気放電灯に適用すること
により,内部のハロゲン化金属の飛散を抑制し放電灯内
の残量を安定させることができるろう接電極用部品とそ
れを用いた放電灯用ろう接電極とを提供することにあ
る。
Further, another technical problem of the present invention is that
By applying the above brazing electrode parts to a metal vapor discharge lamp, it is possible to suppress the scattering of metal halide inside and stabilize the remaining amount in the discharge lamp, and to use a brazing electrode part using the same. An object of the present invention is to provide a brazing electrode for an electric lamp.

【0024】さらに、本発明のさらにもう一つの技術的
課題は,発光として用いるアルミナガラスとパイプ状
のサポートの熱膨張係数が比較的近く,またパイプ状の
サポートの高温強度が高く封止時のひずみが少ないた
め,封止後の微小リークが発生しにくい金属蒸気放電灯
に用いられるろう接電極用部品とそれを用いた放電灯用
ろう接電極とを提供することにある。
Still another technical problem of the present invention is that an alumina glass used as a light emitting part and a pipe-shaped support have relatively close thermal expansion coefficients, and the pipe-shaped support has a high high-temperature strength and is difficult to seal. It is an object of the present invention to provide a brazing electrode component used for a metal vapor discharge lamp in which a small leak after sealing is less likely to occur because of little distortion, and a brazing electrode for a discharge lamp using the same.

【0025】[0025]

【課題を解決するための手段】本発明によれば、放電灯
の電極に用いられる電極用部品であって、Mo又はMo
合金からなる板材を曲げ加工により筒状に成形し,周方
向の端部を互いに突き合わせて,第1のろう材を用いた
ろう接により接合しパイプ状に形成したことを特徴とす
放電灯のろう接電極用部品が得られる。
According to the present invention, a discharge lamp is provided.
An electrode component used for the electrode of claim 1, wherein Mo or Mo
A discharge lamp having a pipe shape formed by bending a plate material made of an alloy into a cylindrical shape by bending, joining ends in a circumferential direction to each other, and joining them by brazing using a first brazing material. The parts for contact electrodes are obtained.

【0026】また、本発明によれば、前記放電灯のろう
接電極用部品において,前記板材は,0.1〜1.0%
未満のランタン又はランタン酸化物と,残部がモリブデ
ンとからなり,実質的に一定方向に伸長して再結晶化し
ているインターロッキング構造を呈する結晶粒子を有し
ていることを特徴とする放電灯のろう接電極用部品が得
られる。
According to the present invention, in the component for a brazing electrode of the discharge lamp , the plate material is 0.1 to 1.0%.
Lanthanum or lanthanum oxide of less than, and the balance of molybdenum, of the discharge lamp, characterized in that it has a crystal grain that exhibits interlocking structures and recrystallized substantially elongated in a predetermined direction A component for a brazing electrode is obtained.

【0027】また、本発明によれば、前記いずれか一つ
の放電灯のろう接電極用部品において,前記第1のろう
材は,Ru−Mo共晶合金に,硼素(B)を1.4重量
%から3.0重量%添加したものから実質的になること
を特徴とする放電灯のろう接電極用部品が得られる。
Further, according to the present invention, any one of the above-mentioned ones
In the discharge lamp brazing electrode part, the first brazing material is substantially composed of a Ru-Mo eutectic alloy to which boron (B) is added in an amount of 1.4 wt% to 3.0 wt%. Thus, there can be obtained a component for a brazing electrode of a discharge lamp .

【0028】また、本発明によれば、前記いずれか一つ
の放電灯のろう接電極用部品を用い,前記パイプ状のろ
う接電極用部品の接合部内側に棒状のW又はW合金から
なる電極を第2のろう材を用いたろう接により接合した
ことを特徴とする放電灯用ろう接電極が得られる。
Further, according to the present invention, any one of the above
And that a rod-shaped electrode made of W or a W alloy was joined to the inside of the joint of the pipe-shaped brazing electrode component by brazing using a second brazing material. A characteristic soldering electrode for a discharge lamp is obtained.

【0029】また,本発明によれば,前記放電灯用ろう
接電極において,前記第2のろう材と前記第1のろう材
とは,同じ材料からなり,前記パイプ状に形成すること
と前記棒状のW又はW合金からなる電極をこのパイプに
接合することとは同時に行われていることを特徴とする
放電灯用ろう接電極が得られる。
According to the present invention, in the brazing electrode for a discharge lamp, the second brazing material and the first brazing material are made of the same material and are formed in the pipe shape. It is possible to obtain a brazing electrode for a discharge lamp, which is characterized in that the rod-shaped electrode made of W or W alloy is joined to the pipe at the same time.

【0030】また,本発明によれば,前記いずれかの放
電灯用ろう接電極において,前記第1及び第2のろう材
は,夫々Ru−Mo共晶合金に硼素(B)を1.4重量
%から3.0重量%添加したものから実質的になること
を特徴とする放電灯用ろう接電極が得られる。
Further, according to the present invention, in any one of the brazing electrodes for a discharge lamp, the first and second brazing materials are each made of Ru-Mo eutectic alloy containing 1.4 parts of boron (B). Thus, a brazing electrode for a discharge lamp is obtained, which is substantially composed of an addition of from 3.0% by weight to 3.0% by weight.

【0031】また,本発明によれば,前記放電灯用ろう
接電極用部品において,前記第2のろう材は,前記第1
のろう材よりも低融点であることを特徴とする放電灯用
ろう接電極が得られる。
According to the present invention, in the component for a brazing electrode for a discharge lamp, the second brazing material may include the first brazing material.
Thus, a brazing electrode for a discharge lamp characterized by having a lower melting point than the brazing material is obtained.

【0032】さらに,本発明によれば,前記放電灯用ろ
う接電極において,前記第1及び第2のろう材は,夫々
Ru−Mo共晶合金に硼素(B)を1.4重量%から
3.0重量%添加したものから実質的になり,前記第1
のろう材の硼素(B)含有量は,前記第2のろう材の硼
素(B)含有量よりも少いことを特徴とする放電灯用ろ
う接電極が得られる。ここで、本発明において、放電灯
用ろう接合電極とは、放電灯に用いられる電極であっ
て、ろう接合によって形成されるろう接部を備えている
電極を呼ぶ。また、ろう接用電極部品とは、この放電灯
用ろう接電極等のろう接電極を構成するのみ用いられる
一部品を呼ぶ。
Further, according to the present invention, in the brazing electrode for a discharge lamp, the first and second brazing materials are each composed of a Ru—Mo eutectic alloy containing boron (B) in an amount of 1.4% by weight. 3.0% by weight.
A brazing electrode for a discharge lamp, characterized in that the content of boron (B) in the brazing material is smaller than the content of boron (B) in the second brazing material. Here, in the present invention, the discharge lamp
A solder joint electrode is an electrode used for a discharge lamp.
And has a brazing portion formed by brazing
Call the electrodes. Also, the soldering electrode part is the discharge lamp
Used only to form brazing electrodes such as brazing electrodes
Call one part.

【0033】[0033]

【発明の実施の形態】以下,本発明の実施の形態につい
て図面を参照して説明する。図1は,本発明の実施の形
態によるろう接電極用部品を適用した金属蒸気放電灯の
概略断面図である。なお,図1は,片側電極部のみに,
パイプ状サポートであるろう接電極用部品を適用した例
を示すが,必要に応じて両側の電極部に使用してもよ
い。図1を参照すると,金属蒸気放電灯10は,両端に
互いに対向した対向端にWコイル11を備えた放電電極
であるW電極12,12を夫々備えている。一端のW電
極12は,W電極12のパイプ状サポートであるろう接
電極用部品1を介して抵抗溶接等によってMoリード1
4に接続されている。ここで、Wコイル11を備えた放
電電極であるW電極12とろう接電極用部品1とで、ろ
う接電極を構成している。一方,他端のW電極12は,
従来と同様に,Mo箔13を介して,Moリード14に
抵抗溶接等によって,接続している。
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic sectional view of a metal vapor discharge lamp to which a brazing electrode component according to an embodiment of the present invention is applied. FIG. 1 shows only one side of the electrode,
An example is shown in which a brazing electrode part, which is a pipe-shaped support, is applied, but it may be used for both electrode parts as needed. Referring to FIG. 1, a metal vapor discharge lamp 10 is provided with W electrodes 12, 12 which are discharge electrodes having W coils 11 at opposite ends opposite to each other. The W electrode 12 at one end is connected to the Mo lead 1 by resistance welding or the like via a brazing electrode part 1 which is a pipe-like support for the W electrode 12.
4 is connected. Here, a discharge coil having the W coil 11 is used.
The W electrode 12 which is an electrode and the soldering electrode component 1
This constitutes a contact electrode. On the other hand, the W electrode 12 at the other end is
As in the conventional case, the Mo lead 13 is connected to the Mo lead 14 via the Mo foil 13 by resistance welding or the like.

【0034】これらの放電電極は,放電発光部を構成す
るアルミナガラス管15の端面に封入されている。これ
らの部品の組み立て後に,ハロゲン金属封入物16をア
ルミナガラス管15に投入して,約1500℃にして加
熱封止している。
These discharge electrodes are sealed at the end face of an alumina glass tube 15 constituting a discharge light emitting portion. After assembling these parts, the halogen metal fill 16 is put into the alumina glass tube 15 and heated to about 1500 ° C. for heat sealing.

【0035】図2は図1の金属蒸気放電灯のろう接電極
用部品1を主に示す概略構成図で,(a)は縦断面図,
(b)は横断面図である。図2(a)及び(b)を参照
すると,ろう接電極用部品1は,折り曲げによって形成
された円筒形状のモリブデン(Mo)母材7の円周方向
の端面同士を第1のろう材5を介して接合するととも
に,W電極12の一端も第2のろう材6によって同時に
接合している。このように,ろう接電極用部品1を金属
蒸気放電灯に適用することにより,内部のハロゲン化金
属の飛散を抑制し放電灯内の残量を安定させることがで
きる。さらに,アルミナガラスとMoパイプの熱膨張係
数が比較的近く,またMoパイプの高温強度が高く封止
時のひずみが少ないため,封止後の微小リークが発生し
にくい金属蒸気放電灯が得られる。
FIG. 2 is a schematic structural view mainly showing the brazing electrode part 1 of the metal vapor discharge lamp of FIG. 1, (a) is a longitudinal sectional view,
(B) is a cross-sectional view. With reference to FIGS. 2A and 2B, the brazing electrode component 1 is configured such that circumferential end surfaces of a cylindrical molybdenum (Mo) base material 7 formed by bending are joined to a first brazing material 5. And one end of the W electrode 12 is also simultaneously joined by the second brazing material 6. As described above, by applying the brazing electrode component 1 to a metal vapor discharge lamp, scattering of the metal halide inside can be suppressed, and the remaining amount in the discharge lamp can be stabilized. Furthermore, since the thermal expansion coefficient of the alumina glass and the Mo pipe is relatively close, and the high temperature strength of the Mo pipe is high and the distortion at the time of sealing is small, it is possible to obtain a metal vapor discharge lamp in which a minute leak after sealing is unlikely to occur. .

【0036】ここで,WおよびMo高温用ろう材として
は,たとえば,WおよびMoに対し優れた濡れ性を示す
Ru−Mo共晶合金ろう材が知られているが,このろう
材は融点が1955℃と高温であり,WおよびMo母材
の脆化による強度低下や施工上の問題も多い。
As a high-temperature brazing filler metal for W and Mo, for example, a Ru-Mo eutectic alloy brazing filler alloy exhibiting excellent wettability to W and Mo is known, and this brazing filler metal has a melting point. Since the temperature is as high as 1955 ° C., there are many problems in strength reduction and construction due to embrittlement of W and Mo base materials.

【0037】それに対し,本発明の実施の形態によるろ
う材5及び6は,Ru−Mo共晶合金ろう材に硼素
(B)を適量添加することにより,濡れ性を損なうこと
なく融点を調整することができる。
On the other hand, the melting points of the brazing materials 5 and 6 according to the embodiment of the present invention are adjusted without impairing the wettability by adding an appropriate amount of boron (B) to the Ru—Mo eutectic alloy brazing material. be able to.

【0038】図3はRu−Mo共晶合金(43%Ru−
57%Mo)からなるろう材における硼素(B)の添加
量に対する融点変化を示す図である。図3に示すよう
に,Ru−Mo共晶合金は,硼素(B)添加量が1.5
〜3.0%と増加するについて,1900℃から153
0℃と融点が低下している。尚,本発明の実施の形態に
おいては,ベースとなるRu−Moろう材の組成範囲
は,Ru量で33.5から49.5重量%が使用でき
る。Ru−Moろう材は,この範囲においてRu−Mo
共晶組織を有し,さらには共晶点である43重量%Ru
−57重量%Moが望ましい。
FIG. 3 shows a Ru-Mo eutectic alloy (43% Ru-
It is a figure which shows the melting point change with respect to the addition amount of boron (B) in the brazing material which consists of 57% Mo). As shown in FIG. 3, the Ru—Mo eutectic alloy has a boron (B) addition amount of 1.5%.
From 1900 ° C to 153%
The melting point is lower at 0 ° C. In the embodiment of the present invention, the composition range of the base Ru-Mo brazing material can be 33.5 to 49.5% by weight of Ru. Ru-Mo brazing material is Ru-Mo in this range.
It has a eutectic structure and a eutectic point of 43% by weight Ru.
-57% by weight Mo is desirable.

【0039】また,ろう接温度は,融点より約30℃か
ら50℃高く設定すればよいが,ワークサイズや加熱方
法により変更してもよい。
Further, the brazing temperature may be set at about 30 ° C. to 50 ° C. higher than the melting point, but may be changed depending on the work size and the heating method.

【0040】ろう材の施工方法としては,有機溶剤によ
りペースト状にして塗布する方法が簡便であるが,プレ
ス,圧延あるいは押出し法により薄板あるいは棒状に成
形してもよい。また,成形時,必要に応じて,パラフイ
ン等のバインダーを混合してもよい。ここで,バインダ
ーは,通常のW,Moあるいは超硬合金の成形に用いら
れるものでよく,脱バインダー条件なども同様である。
As a method for applying the brazing material, a method of applying a paste in an organic solvent to form a paste is simple. However, the brazing material may be formed into a thin plate or a rod by pressing, rolling or extrusion. At the time of molding, a binder such as paraffin may be mixed as necessary. Here, the binder may be one used for forming ordinary W, Mo or cemented carbide, and the same applies to the conditions for removing the binder.

【0041】上記のろう材を用いて,曲げ加工を施した
モリブデン素材の突き合わせ部を接合することにより,
接合強度の優れたパイプ状部材が製作できる。
By joining the butted portions of the bent molybdenum material using the above brazing material,
A pipe-shaped member having excellent joining strength can be manufactured.

【0042】ここで,曲げ形状は熱間曲げ,プレスある
いは成形ロールなどにより,樋状,C型形状などに成形
すればよい。
Here, the bent shape may be formed into a gutter shape, a C-shaped shape or the like by hot bending, pressing or forming rolls.

【0043】また,C型形状の継ぎ手部にすき間を残
し,あるいは,C型形状の継ぎ手部に切り込みを入れそ
の部分にW電極12をセットし,同時にろう接してもよ
い。
Alternatively, a gap may be left in the C-shaped joint, or a cut may be made in the C-shaped joint, and the W electrode 12 may be set in that portion and brazed at the same time.

【0044】なお,アルミナガラス管15の封入加工時
の加熱温度は約1500℃であるため,少なくともそれ
以上の融点,好ましくは1600℃以上の融点を持つろ
う材を使用する必要がある。
Since the heating temperature at the time of sealing the alumina glass tube 15 is about 1500 ° C., it is necessary to use a brazing material having a melting point at least higher than that, preferably 1600 ° C. or higher.

【0045】上記のろう材においては,図3に示したも
のと同様に,融点を選択できるため,ろう接電極用部品
1を第1のろう材を用いたろう接により製作した後,よ
り溶融温度の低い第2のろう材を用いたろう接により,
そのろう接電極用部品1のろう接部を溶かすことなくさ
らに別の部材であるW電極12等をろう接することも可
能となる。
In the above brazing material, since the melting point can be selected in the same manner as that shown in FIG. 3, after the brazing electrode part 1 is manufactured by brazing using the first brazing material, the melting temperature is further increased. By brazing using a low brazing second brazing material,
It is also possible to braze another member such as the W electrode 12 without melting the brazing portion of the brazing electrode component 1.

【0046】また,一般には,Mo母材として,純モリ
ブデンがその加工性,コストなどの点から選択される
が,その再結晶温度は約1000℃と低い。さらに高温
で使用されるモリブデン材として,例えば,0.5%T
i,0.07%Zr,および0.05%のCを含むTZ
M(米国クライマックス社の製品名)が知られている
が,TZMにおいても,その再結晶温度は,1300〜
1500℃に過ぎない。そのため,アルミナガラス封止
時約1500℃の加熱により,高温変形,脆化が生じW
電極の位置ずれや脱落などの問題が生じやすい。
In general, pure molybdenum is selected as the Mo base material in view of its workability and cost, but its recrystallization temperature is as low as about 1000 ° C. Further, as a molybdenum material used at a high temperature, for example, 0.5% T
TZ containing i, 0.07% Zr, and 0.05% C
M (product name of U.S.A. Climax) is known, but also in TZM, the recrystallization temperature is 1300-1000.
It is only 1500 ° C. Therefore, high-temperature deformation and embrittlement occur due to heating at about 1500 ° C. when sealing the alumina glass.
Problems such as electrode displacement and dropping are likely to occur.

【0047】それに対し,特公平2−38659号公報
に示されるように,再結晶温度後においても加工性およ
び耐高温変形性に優れたモリブデン材としてランタン含
有モリブデンがある。このランタン含有モリブデンは,
0.1〜1.0重量%未満のランタンまたはランタン酸
化物と,残部がモリブデンとからなり,実質的に一定方
向に伸長して再結晶化しているインターロッキング構造
を呈する結晶粒子を有する加工性および耐高温変形性に
優れたモリブデン合金である。このランタン含有モリブ
デンを素材として使用することにより,融点が1500
℃以上のろう材を用いても脆化を生じることがなく,か
つ純モリブデンを素材として用いた場合よりも高温使用
時での変形量を小さくできる。
On the other hand, as shown in Japanese Patent Publication No. 2-38659, molybdenum containing lanthanum is a molybdenum material having excellent workability and high temperature deformation resistance even after a recrystallization temperature. This molybdenum containing lanthanum is
Workability having crystalline particles exhibiting an interlocking structure, consisting of lanthanum or lanthanum oxide in an amount of 0.1 to less than 1.0% by weight and molybdenum with the balance being elongated in a certain direction and recrystallized. And a molybdenum alloy having excellent high-temperature deformation resistance. By using this lanthanum-containing molybdenum as a material, a melting point of 1500
Even when a brazing material having a temperature of not less than ℃ is used, no embrittlement occurs, and the amount of deformation at the time of use at a high temperature can be reduced as compared with a case where pure molybdenum is used as a material.

【0048】本発明の実施の形態においては,前記のろ
う材によりろう接処理を行うことにより従来からWおよ
びMo高温用ろう材として用いられてきたRu−Mo共
晶合金ろう材を使用した場合に比べ,ろう接温度を下げ
ることができるため,母材の脆化の恐れが少なく高温強
度の高いモリブデンからなるパイプ状サポートがろう接
により製作可能となり,管引き加工に比し歩留まりが向
上する。
In the embodiment of the present invention, when a brazing treatment is performed using the above-described brazing material, a Ru—Mo eutectic alloy brazing material conventionally used as a W and Mo high-temperature brazing material is used. Since the brazing temperature can be reduced compared to that of pipes, it is possible to manufacture a pipe-shaped support made of molybdenum, which is less likely to become brittle, and has high high-temperature strength, by brazing, thereby improving the yield compared to pipe drawing. .

【0049】さらに,前記パイプ状サポートとW電極を
ろう接により接合可能となり,安定した接合部をもつろ
う接電極部品を提供することができる。
Further, the pipe-shaped support and the W electrode can be joined by brazing, and a brazing electrode component having a stable joint can be provided.

【0050】なお,上記説明において,ろう接電極用部
品1の母材の断面形状をC型形状としたが,例えば,図
4に示すような内側に折り曲げられた端面を持つ形状の
Mo母材3でも,C型形状のMo母材と同様の効果が得
られる。
In the above description, the cross-sectional shape of the base material of the soldering electrode component 1 is C-shaped. However, for example, a Mo base material having an inwardly bent end face as shown in FIG. 3, the same effect as the C-shaped Mo base material can be obtained.

【0051】次に,本発明の実施の形態による放電灯用
ろう接電極の製造の具体例について説明する。
Next, a specific example of the production of the brazing electrode for a discharge lamp according to the embodiment of the present invention will be described.

【0052】(例1)図2(a)及び(b)に示すよう
に,板厚0.1mm.幅20mmの特公平2−3865
9号公報に示されるものと同様のランタン含有モリブデ
ンテープを多軸のフオーミングマシンにより外径1.6
mmのC型断面形状に成形,切断し,ろう接用のMo母
材7とした。ろう接用のMo母材7の長手直線部端面に
融点が約1900℃である42.4重量%Ru−56.
2重量%Mo−1.4重量%Bからなるろう材粉末をバ
インダーによりペースト状にしたろう材5を塗布した
後,治具にて加熱時の位置ずれをふせぎ,真空炉中で毎
分15℃の速度で1950℃まで昇温し,この温度で5
分保持後,徐冷を行いパイプの接合を完了し,図2
(a)及び(b)に示すようなろう接電極用部品1を得
た。この接合処理後,目視外観検査にてMo母材7の隙
間部にろう材が充分流れ,空隙が存在せず,非常に良好
な接合状態が得られていることを確認した。
Example 1 As shown in FIGS. 2 (a) and 2 (b), a sheet thickness of 0.1 mm. 20mm wide, Japanese Patent Publication No. 2-3865
A lanthanum-containing molybdenum tape similar to that shown in JP-A No. 9-2006 is used with a multiaxial forming machine to have an outer diameter of 1.6.
It was formed into a C-shaped cross section of 1 mm and cut to obtain a Mo base material 7 for brazing. The melting point is about 4900% by weight of Ru-56.
After applying the brazing material 5 made of 2% by weight Mo-1.4% by weight B into a paste with a binder, the misalignment at the time of heating is removed by a jig, and the brazing material 5 is placed in a vacuum furnace at a rate of 15% per minute. The temperature was raised to 1950 ° C at a rate of
After holding for one minute, the pipe was gradually cooled to complete the joining of the pipes.
A brazing electrode part 1 as shown in (a) and (b) was obtained. After this joining process, it was confirmed by visual inspection that the brazing material sufficiently flowed into the gaps of the Mo base material 7, that no voids existed, and that a very good joining state was obtained.

【0053】その後,ろう接母材のC型形状の周面端部
の突き合わせ部に直径0.5mm,長さ16mmのW線
の片端面から8mmの範囲に融点が約1600℃である
41.8重量%Ru−55.4重量%Mo−2.8重量
%Bからなるろう材粉末をバインダーによりペースト状
にしたろう材6を塗布した後,W電極12用のW線を突
き出し長さが8mmとなる位置にろう材6を塗布した部
分がろう接用のMo母材7に接するようにセットし,さ
らに治具にて位置ずれおよび変形をふせぎ,真空炉中で
毎分15℃の昇温速度で1650℃まで昇温し,この温
度で5分保持後,徐冷を行い接合を完了した。この接合
処理後においても,目視外観検査にて母材との隙間部に
ろう材が充分流れ,空隙が存在せず,非常に良好な接合
状態が得られていることを確認した。また,前記のろう
接電極用部品1のろう接部に変化が生じていないことを
も確認した。
Thereafter, the melting point is about 1600 ° C. in a range of 8 mm from one end face of the W wire having a diameter of 0.5 mm and a length of 16 mm at the abutting portion of the C-shaped peripheral end of the brazing base material 41. After applying a brazing material 6 in which a brazing material powder consisting of 8 wt% Ru-55.4 wt% Mo-2.8 wt% B was made into a paste with a binder, a W line for the W electrode 12 was projected and the length was protruded. At a position of 8 mm, the portion where the brazing material 6 was applied was set so as to be in contact with the Mo base material 7 for brazing, and further displacement and deformation were prevented with a jig, and the temperature was raised at 15 ° C./min in a vacuum furnace. The temperature was raised to 1650 ° C. at a temperature rate and maintained at this temperature for 5 minutes, followed by slow cooling to complete the joining. Even after this joining process, it was confirmed by visual appearance inspection that the brazing material sufficiently flowed into the gap with the base material, that no void existed, and that a very good joining state was obtained. Also, it was confirmed that no change occurred in the brazing portion of the brazing electrode part 1.

【0054】上記ろう接電極の長さの半分ほどを,図1
に示すアルミナガラス管15の一端に挿入,封止した。
他端は,通常のMo箔13を介してMoリード14に接
続され,アルミナガラス管15の端面で封入されている
構造とした。その後,ろう接電極の開口部1aよりハロ
ゲン化金属を投入し,次いでその開口部1aに別途用意
したMoキャップ17を備えたMoリード14を挿入し
市販の銀ロウにてろう接封止して放電灯の発光部10を
得た。この場合,ろう接電極の開口部1a封止の際,加
熱部がハロゲン化金属の存在する部分から離れているた
め,ハロゲン化金属の蒸発,飛散を確実に防止すること
ができた。また,アルミナガラス管15とろう接電極用
部品1であるMoパイプの熱膨張係数が比較的近く,ま
た,Moパイプの高温強度が高く封止時のひずみが少な
いため,封止後の微小リークの発生も認められなかっ
た。
About half of the length of the soldering electrode is
Was inserted into one end of an alumina glass tube 15 and sealed.
The other end is connected to a Mo lead 14 via a normal Mo foil 13 and is sealed at an end face of an alumina glass tube 15. Thereafter, a metal halide is introduced through the opening 1a of the brazing electrode, and then a Mo lead 14 having a separately prepared Mo cap 17 is inserted into the opening 1a and brazed and sealed with a commercially available silver solder. The light emitting part 10 of the discharge lamp was obtained. In this case, when the opening 1a of the brazing electrode was sealed, the heating portion was separated from the portion where the metal halide was present, so that evaporation and scattering of the metal halide could be reliably prevented. In addition, since the thermal expansion coefficient of the alumina glass tube 15 and the Mo pipe which is the soldering electrode part 1 is relatively close, and the high temperature strength of the Mo pipe is high and the distortion at the time of sealing is small, a minute leak after sealing is obtained. No occurrence was observed.

【0055】(例2)図2(a)及び(b)に示すよう
に,板厚0.1mm,幅20mmの特公平2−3865
9号公報に示されたランタン含有モリブデンテープを多
軸のフォーミングマシンにより,外径1.6mmのC型
形状に成形,切断しろう接用のMo母材7とした。ろう
接用のMo母材7の長手直線部端面に,融点が約170
0℃である42.1重量%Ru−55.7重量%Mo−
2.2重量%Bからなるろう材粉末をバインダーにより
ペースト状にしたろう材5を塗布した後,直径0.5m
m,長さ16mmのW電極12用のW線を突き出し長さ
が8mmとなる位置にろう材を塗布した部分がろう接母
材突き合わせ部にセットし,真空炉中で毎分15℃の速
度で1750℃まで昇温し,この温度で5分保持後,徐
冷を行い接合を完了した。
(Example 2) As shown in FIGS. 2A and 2B, a Japanese Patent Publication No. 2-3865 having a thickness of 0.1 mm and a width of 20 mm was used.
The lanthanum-containing molybdenum tape disclosed in Japanese Patent No. 9 was formed into a C-shape having an outer diameter of 1.6 mm by a multiaxial forming machine and cut to obtain a Mo base material 7 for brazing. A melting point of about 170 was applied to the end face of the longitudinal straight portion of the Mo base material 7 for brazing.
42.1 wt% Ru-55.7 wt% Mo- at 0 ° C.
After applying the brazing filler metal 5 made of a paste of 2.2 wt% B using a binder, the diameter is 0.5 m.
m, a W wire for a W electrode 12 having a length of 16 mm is protruded, and a portion where the brazing material is applied is set at a position where the length becomes 8 mm, at a brazing base material butt portion, and a speed of 15 ° C./min in a vacuum furnace. The temperature was raised to 1750 ° C. and held at this temperature for 5 minutes, followed by slow cooling to complete the joining.

【0056】この接合処理後,目視外観検査にて母材隙
間部にろう材が充分流れ,空隙が存在せず,非常に良好
な接合状態が得られていることを確認した。
After the joining process, it was confirmed by visual inspection that the brazing material sufficiently flowed into the gaps between the base materials, that no gaps existed, and that a very good joining state was obtained.

【0057】さらに,上記例1と同様にして放電灯を製
作することにより,ハロゲン化金属の蒸発,飛散の防止
効果,およびアルミナガラスとの良好な封止性を確認で
きた。
Further, by manufacturing a discharge lamp in the same manner as in Example 1, it was possible to confirm the effect of preventing the metal halide from evaporating and scattering, and the good sealing property with the alumina glass.

【0058】[0058]

【発明の効果】以上,説明したように,本発明によれ
ば,接合強度に優れ母材の脆化の恐れの少ないパイプ状
サポートがろう接により製作可能となり,さらに,前記
パイプ状サポートとW電極もろう接により接合可能とな
り,安定した接合部をもつろう接電極用部品と放電灯用
ろう接電極とを提供することができる。
As described above, according to the present invention, it is possible to manufacture a pipe-shaped support having excellent joining strength and less risk of embrittlement of the base material by brazing, and furthermore, the pipe-shaped support and W The electrodes can also be joined by brazing, so that a brazing electrode component and a brazing electrode for a discharge lamp having a stable joint can be provided.

【0059】また,本発明のろう接電極部品を金属蒸気
放電灯に適用することにより,内部のハロゲン化金属の
飛散を抑制し放電灯内の残量を安定させることができる
放電灯が得られるろう接電極用部品と放電灯用ろう接電
極とを提供することができる。
Further, by applying the brazing electrode part of the present invention to a metal vapor discharge lamp, a discharge lamp capable of suppressing the scattering of metal halide inside and stabilizing the remaining amount in the discharge lamp can be obtained. A brazing electrode component and a brazing electrode for a discharge lamp can be provided.

【0060】さらに,本発明によれば,アルミナガラス
とMoパイプの熱膨張係数が比較的近く,またMoパイ
プの高温強度が高く封止時のひずみが少ないため,封止
後の微小リークが発生しにくい金属蒸気放電灯が得られ
るろう接電極用部品と放電灯用ろう接電極とを提供する
ことができる。
Further, according to the present invention, since the thermal expansion coefficient of the alumina glass and the Mo pipe is relatively close, and the high temperature strength of the Mo pipe is high and the distortion at the time of sealing is small, a small leak after sealing is generated. It is possible to provide a brazing electrode component and a brazing electrode for a discharge lamp that can provide a metal vapor discharge lamp that is difficult to perform.

【図面の簡単な説明】[Brief description of the drawings]

【図1】本発明の実施の形態によるろう接電極用部品を
用いた金属蒸気放電灯を示す概略断面図である。
FIG. 1 is a schematic sectional view showing a metal vapor discharge lamp using a brazing electrode component according to an embodiment of the present invention.

【図2】図2は図1のろう接電極用部品を主に示す概略
断面図であり,(a)は縦断面図,(b)は横断面図で
ある。
FIGS. 2A and 2B are schematic sectional views mainly showing the soldering electrode component of FIG. 1, wherein FIG. 2A is a longitudinal sectional view and FIG. 2B is a transverse sectional view.

【図3】Ru−Mo共晶合金からなるろう材の硼素
(B)添加量と融点との関係を示す図である。
FIG. 3 is a diagram showing the relationship between the amount of boron (B) added and the melting point of a brazing filler metal made of a Ru—Mo eutectic alloy.

【図4】発明の実施の形態によるろう接電極用部品の
母材の例を示す横断面図である。
FIG. 4 is a cross-sectional view showing an example of a base material of the brazing electrode component according to the embodiment of the present invention.

【図5】従来の金属蒸気放電灯の一例を示す概略断面図
である。
FIG. 5 is a schematic sectional view showing an example of a conventional metal vapor discharge lamp.

【符号の説明】[Explanation of symbols]

1 ろう接電極用部品 1a 開口部3,7 Mo母材 5 第1のろう材 6 第2のろう材 10,50 金属蒸気放電灯 11 Wコイル 12 W電極 13 Mo箔 14 Moリード 15 アルミナガラス管 16 ハロゲン金属封入物 17 Moキャップ DESCRIPTION OF SYMBOLS 1 Brazing electrode component 1a Opening 3,7 Mo base material 5 1st brazing material 6 2nd brazing material 10,50 Metal vapor discharge lamp 11 W coil 12 W electrode 13 Mo foil 14 Mo lead 15 Alumina glass tube 16 Halogen metal filling 17 Mo cap

───────────────────────────────────────────────────── フロントページの続き (56)参考文献 特開 昭56−35345(JP,A) 特開 平10−244363(JP,A) 特開 平5−57429(JP,A) 実開 昭59−16067(JP,U) 特公 平2−38659(JP,B2) (58)調査した分野(Int.Cl.7,DB名) H01J 61/36 H01J 9/04 H01J 9/28 H01J 61/073 ──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-56-35345 (JP, A) JP-A-10-244363 (JP, A) JP-A-5-57429 (JP, A) 16067 (JP, U) JP 2-38659 (JP, B2) (58) Fields investigated (Int. Cl. 7 , DB name) H01J 61/36 H01J 9/04 H01J 9/28 H01J 61/073

Claims (8)

(57)【特許請求の範囲】(57) [Claims] 【請求項1】 放電灯の電極に用いられる電極用部品で
あって、Mo又はMo合金からなる板材を曲げ加工によ
り筒状に成形し,周方向の端部を互いに突き合わせて,
第1のろう材を用いたろう接により接合しパイプ状に形
成したことを特徴とする放電灯のろう接電極用部品。
An electrode part used for an electrode of a discharge lamp.
Then, a plate material made of Mo or Mo alloy is formed into a tubular shape by bending, and the ends in the circumferential direction are abutted with each other.
A part for a brazing electrode of a discharge lamp, wherein the part is formed into a pipe shape by brazing using a first brazing material.
【請求項2】 請求項1記載の放電灯のろう接電極用部
品において,前記板材は,0.1〜1.0%未満のラン
タン又はランタン酸化物と,残部がモリブデンとからな
り,実質的に一定方向に伸長して再結晶化しているイン
ターロッキング構造を呈する結晶粒子を有していること
を特徴とする放電灯のろう接電極用部品。
2. The component for a brazing electrode of a discharge lamp according to claim 1, wherein said plate material is composed of lanthanum or lanthanum oxide in an amount of 0.1 to less than 1.0%, and the balance is substantially molybdenum. A component for a soldering electrode of a discharge lamp, characterized by having crystal grains exhibiting an interlocking structure which are elongated in a certain direction and recrystallized.
【請求項3】 請求項1又は2記載の放電灯のろう接電
極用部品において,前記第1のろう材は,Ru−Mo共
晶合金に,硼素(B)を1.4重量%から3.0重量%
添加したものから実質的になることを特徴とする放電灯
ろう接電極用部品。
3. The component for a brazing electrode of a discharge lamp according to claim 1, wherein the first brazing material is a Ru—Mo eutectic alloy containing 1.4% by weight of boron (B). 0.0% by weight
Discharge lamp characterized by being substantially composed of added substances
Parts for soldering electrodes.
【請求項4】 請求項1又は2記載の放電灯のろう接電
極用部品を用い,前記パイプ状のろう接電極用部品の接
合部内側に棒状のW又はW合金からなる電極を第2のろ
う材を用いたろう接により接合したことを特徴とする放
電灯用ろう接電極。
4. A rod-shaped electrode made of W or W alloy is provided on the inner side of a joint of the pipe-shaped brazing electrode part, using the brazing electrode part of a discharge lamp according to claim 1 or 2. A brazing electrode for a discharge lamp, which is joined by brazing using a brazing material.
【請求項5】 請求項4記載の放電灯用ろう接電極にお
いて,前記第2のろう材と前記第1のろう材とは,同じ
材料からなり,前記パイプ状に形成することと前記棒状
のW又はW合金からなる電極をこのパイプに接合するこ
ととは同時に行われていることを特徴とする放電灯用ろ
う接電極。
5. The brazing electrode for a discharge lamp according to claim 4, wherein the second brazing material and the first brazing material are made of the same material, and are formed in the pipe shape and the rod shape. A brazing electrode for a discharge lamp, wherein the joining of an electrode made of W or a W alloy to the pipe is performed at the same time.
【請求項6】 請求項4又は5に記載の放電灯用ろう接
電極において,前記第1及び第2のろう材は,夫々Ru
−Mo共晶合金に硼素(B)を1.4重量%から3.0
重量%添加したものから実質的になることを特徴とする
放電灯用ろう接電極。
6. The brazing electrode for a discharge lamp according to claim 4, wherein the first and second brazing materials are each made of Ru.
-Mo (E) eutectic alloy containing boron (B) from 1.4% by weight to 3.0%.
A brazing electrode for a discharge lamp, which is substantially composed of a substance added by weight%.
【請求項7】 請求項4記載の放電灯用ろう接電極にお
いて,前記第2のろう材は,前記第1のろう材よりも低
融点であることを特徴とする放電灯用ろう接電極。
7. The brazing electrode for a discharge lamp according to claim 4, wherein the second brazing material has a lower melting point than the first brazing material.
【請求項8】 請求項7記載の放電灯用ろう接電極にお
いて,前記第1及び第2のろう材は,夫々Ru−Mo共
晶合金に硼素(B)を1.4重量%から3.0重量%添
加したものから実質的になり,前記第1のろう材の硼素
(B)含有量は,前記第2のろう材の硼素(B)含有量
よりも少いことを特徴とする放電灯用ろう接電極。
8. The brazing electrode for a discharge lamp according to claim 7, wherein the first and second brazing materials are each composed of a Ru-Mo eutectic alloy containing 1.4% by weight of boron (B). The first brazing material has a boron (B) content smaller than the boron (B) content of the second brazing material. Brazing electrode for electric lights.
JP01288098A 1998-01-26 1998-01-26 Brazing electrode parts and brazing electrodes for discharge lamps Expired - Fee Related JP3309309B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP01288098A JP3309309B2 (en) 1998-01-26 1998-01-26 Brazing electrode parts and brazing electrodes for discharge lamps

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP01288098A JP3309309B2 (en) 1998-01-26 1998-01-26 Brazing electrode parts and brazing electrodes for discharge lamps

Publications (2)

Publication Number Publication Date
JPH11213946A JPH11213946A (en) 1999-08-06
JP3309309B2 true JP3309309B2 (en) 2002-07-29

Family

ID=11817735

Family Applications (1)

Application Number Title Priority Date Filing Date
JP01288098A Expired - Fee Related JP3309309B2 (en) 1998-01-26 1998-01-26 Brazing electrode parts and brazing electrodes for discharge lamps

Country Status (1)

Country Link
JP (1) JP3309309B2 (en)

Families Citing this family (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE102007050487A1 (en) * 2007-10-19 2009-04-30 W.C. Heraeus Gmbh High temperature solder for the production of discharge lamp by a solder connection between a tungsten-based electrode and molybdenum-based supporting bar, comprises molybdenum and ruthenium as main component, and further metals
JP4667441B2 (en) * 2007-10-31 2011-04-13 東芝ホクト電子株式会社 Brazing material, tube, magnetron and brazing method
JP5316436B2 (en) * 2010-01-28 2013-10-16 ウシオ電機株式会社 Discharge lamp
JP5093304B2 (en) * 2010-07-02 2012-12-12 ウシオ電機株式会社 Short arc type discharge lamp
JP5218582B2 (en) * 2011-03-08 2013-06-26 ウシオ電機株式会社 Discharge lamp

Also Published As

Publication number Publication date
JPH11213946A (en) 1999-08-06

Similar Documents

Publication Publication Date Title
US5418072A (en) Totally consumable brazing encapsulate for use in joining aluminum surfaces
US8020749B2 (en) Dissimilar metal joining method
US7946467B2 (en) Braze material and processes for making and using
US7156282B1 (en) Titanium-aluminide turbine wheel and shaft assembly, and method for making same
KR101589918B1 (en) Heat transfer tube and method for producing same
US20080014458A1 (en) Filler for Joint and Method for Production Thereof
JP2000117484A (en) Seamless ring-shaped brazing material and manufacture thereof
EP2703112B1 (en) Method for producing laser welded steel pipe
JP3309309B2 (en) Brazing electrode parts and brazing electrodes for discharge lamps
JP2006224147A (en) Method for joining different materials and filler metal therefor
KR20130069433A (en) Manufacturing method of heat exchanger, and heat exchanger manufactured by such manufacturing method
JP3327819B2 (en) How to join metal materials
JP3783975B2 (en) Brazing method
JPH10244363A (en) High melting point metal brazed cylindrical member and manufacture thereof
JPH05277742A (en) Contact tip and its manufacture
JPH09248668A (en) Gas shielded consumable electrode arc brazing method
JP3822108B2 (en) Composite pipe for brazing and heat exchange composite pipe
JP3975225B1 (en) Fluorescent discharge lamp electrode and manufacturing method thereof
CN110193682B (en) Brazing filler metal and preparation method thereof
JP3975223B1 (en) Fluorescent discharge lamp electrode and manufacturing method thereof
JP2007268603A (en) Laser brazing method of lap fillet welded joint
JPH1061622A (en) Airtight joint
JPH06190574A (en) Laser beam welding method for copper structure
EP0495588A2 (en) Welding auxiliary material
JP2007207695A (en) Electrode for fluorescent discharge lamp, and its manufacturing method

Legal Events

Date Code Title Description
A02 Decision of refusal

Free format text: JAPANESE INTERMEDIATE CODE: A02

Effective date: 20011219

A01 Written decision to grant a patent or to grant a registration (utility model)

Free format text: JAPANESE INTERMEDIATE CODE: A01

Effective date: 20020424

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20080524

Year of fee payment: 6

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20090524

Year of fee payment: 7

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20090524

Year of fee payment: 7

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20100524

Year of fee payment: 8

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20100524

Year of fee payment: 8

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20110524

Year of fee payment: 9

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20120524

Year of fee payment: 10

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20130524

Year of fee payment: 11

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20130524

Year of fee payment: 11

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

LAPS Cancellation because of no payment of annual fees